Spontaneous emission and energy transfer rates near a coated metallic cylinder

Karanikolas, Vasilios; Marocico, Cristian A.; Bradley, A. Louise

doi:10.1103/physreva.89.063817

Cited by 28 publications

(28 citation statements)

References 56 publications

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“…Further, plasmon coupling would influence the absorption and release energy of gold nanoparticles 14,17,19,51 . Therefore, the size, shape and composition of the plasmonic nanostructures can be adapted to obtain broad absorption 6,11,18,52 . Radiative recombination in Au NPs has been observed aris-ing from transitions between electrons in conduction-band states below the Fermi level and holes in the d bands generated by optical excitation 17,19,20,53 .…”

Section: Resultsmentioning

confidence: 99%

“…Interestingly, the inverse process, namely, of generating photons from non-equilibrium electrons in metal nanostructures themselves, can be facilitated by resonant plasmons, as well. Consequently, PL in gold nanoparticles has been ascribed to the radiative damping of particle plasmons generated by the recombination of sp band electrons and excited d band holes 11,18 .…”

Section: Introductionmentioning

confidence: 99%

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Electrically driven plasmon mediated energy transfer between ZnO microwires and Au nanoparticles

et al. 2015

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Electrically driven energy transfer between the surface defect states of ZnO quadrilateral microwires (MWs) and localized surface plasmon polaritons has been realized by means of introducing Au nanoparticles (NPs). An electroluminescence device with green emission using ZnO quadrilateral MWs, was fabricated. Once the Au NPs are sputtered on the surfaces of the ZnO MWs, the electroluminescence of the ZnO MWs will shift from green to red. Meanwhile, dual emissions were observed by means of sputtering Au NPs on a single ZnO MW periodically. Due to the Au NPs, electrically driven plasmon mediated energy transfer can achieve the modulation of amplifying, or quenching the surface defect emission. The relevant dynamic process of the surface plasmon mode mediated energy transfer was investigated. This new energy transfer method potentially offers an approach of modification and recombination of the surface defect state excitations of wide bandgap semiconductor materials.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Electrically driven plasmon mediated energy transfer between ZnO microwires and Au nanoparticles

et al. 2015

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“…In this paper we consider a cylindrical dielectric core coated with a graphene layer and we investigate the role of the LSPs in modifying the emission and radiation rates of an emitter placed inside the graphene-coated cylinder. In this context, several works focused on the influence that the eigenmodes play on circular dielectric and metallic waveguides [17,18,19] or on single wall carbon nanotubes [20]. Such systems offer a new tool for the interplay between light and matter at the nanometer scale [21,22].…”

Section: Introductionmentioning

confidence: 99%

Graphene coated subwavelength wires: a theoretical investigation of emission and radiation properties

Cuevas

2017

Journal of Quantitative Spectroscopy and Radiative Transfer

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This work analyzes the emission and radiation properties of a single optical emitter embedded in a graphene-coated subwavelength wire. We discuss the modifications of the spontaneous emission rate and the radiation efficiency as a function of the position and orientation of the dipole inside the wire. Our results show that these quantities can be enhanced by several orders of magnitude when the emission frequency coincides with one of the resonance frequencies of the graphene-coated wire. In particular, high-order plasmon resonances are excited when the emitter is moved from the wire center. The modifications by varying the orientation of the dipole in the near field distribution and in the far field intensities are shown.

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“…Finally, since an emitter can be efficiently coupled to a surface plasmon, it has been proposed to use plasmon to couple two emitters for applications such as long range resonant energy transfer (above 10 nm) [93,94,95,96,97] or qubits entanglement [98,99]. In the following, we discuss the plasmonic Purcell factor for typical configurations.…”

Section: Dipole-dipole Couplingmentioning

confidence: 99%

Plasmonic Purcell factor and coupling efficiency to surface plasmons. Implications for addressing and controlling optical nanosources

Francs

Barthès

Bouhélier

et al. 2016

J. Opt.

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Abstract. The Purcell factor Fp is a key quantity in cavity quantum electrodynamics (cQED) that quantifies the coupling rate between a dipolar emitter and a cavity mode. Its simple form Fp ∝ Q/V unravels the possible strategies to enhance and control light-matter interaction. Practically, efficient light-matter interaction is achieved thanks to either i) high quality factor Q at the basis of cQED or ii) low modal volume V at the basis of nanophotonics and plasmonics. In the last decade, strong efforts have been done to derive a plasmonic Purcell factor in order to transpose cQED concepts to the nanocale, in a scale-law approach. In this work, we discuss the plasmonic Purcell factor for both delocalized (SPP) and localized (LSP) surface-plasmon-polaritons and briefly summarize the expected applications for nanophotonics. On the basis of the SPP resonance shape (Lorentzian or Fano profile), we derive closed form expression for the coupling rate to delocalized plasmons. The quality factor factor and modal confinement of both SPP and LSP are quantified, demonstrating their strongly subwavelength behaviour.

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Spontaneous emission and energy transfer rates near a coated metallic cylinder

Cited by 28 publications

References 56 publications

Electrically driven plasmon mediated energy transfer between ZnO microwires and Au nanoparticles

Electrically driven plasmon mediated energy transfer between ZnO microwires and Au nanoparticles

Graphene coated subwavelength wires: a theoretical investigation of emission and radiation properties

Plasmonic Purcell factor and coupling efficiency to surface plasmons. Implications for addressing and controlling optical nanosources

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